• Economic and Environmental Geology
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• v.48 no.4
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• pp.287-299
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• 2015

The metapsammite distributed in the Yeongam-Gangjin area had been classified into age-unknown Yongamsan Formation, Seologri Formation and age-unknown Seogisan Formation, and these formations are reported as each other different formations. These formations have been renamed Precambrian Galdu or Permian Songjong Formations. In this study, we present detrital zircon SHRIMP U-Pb age data from the metapsammite to examine deposition time and stratigraphy. The analyzed U-Pb zircon ages dominantly reveal Paleoproterozoic ages of ca. 1.87Ga and the youngest detrital grains are constrained by the age of 246-265 Ma. The youngest age indicates late Permian or early Triassic for the deposition time. Therefore, the metapsammite in the Yeongam-Gangjin area is considered to be the upper formation of the late Paleozoic Pyeongan Group which is correlated with the Gohan-Donggo Formations or Nokam Formation of the Samcheock coal field and the Cheonunsan Formation of the Hwasun coal field. The metapsammite of the study area is the late Paleozoic Pyeongan Group by the zircon age rather than Precambrian Galdu and Permian Songjeong Formations are no longer meaningful. Therefore, we propose the upper Paleozoic 'metapelite' and 'metaspammite', or original formation name defined by 1:50,000 geological maps, instead of Galdu and Songjeong Formations.

• 한국석유지질학회:학술대회논문집
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• autumn
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• pp.28-28
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• 2000

• The Journal of the Petrological Society of Korea
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• v.24 no.1
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• pp.55-63
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• 2015

We investigated the zircon U-Pb ages of the metapelites from the Sungjeon-myeon Gangjin-gun, the southwestern Ogcheon belt, to provide geochronological constraints for the depositional age as well as the distribution of Late Paleozoic formation. Data from the detrital zircons are mostly concordant, yielding four major age groups: (1) Neoarchean (~2.5 Ga); (2) Paleoproterozoic (~1.86 Ga, Statherian); (3) Middle Devonian(~390 Ma); and (4) Late Paleozoic (~322 Ma, Serpukhobian). The youngest zircon age gives a weighted mean $^{206}Pb/^{238}U$ age of $322{\pm}4.8$ Ma (n=16, MSWD=4.9), indicating deposition age of Early Carboniferous(Serpukhobian) or after. Therefore, the metapelites is considered to be the lowest Formation of the late Paleozoic Pyeongan Supergroup correlated with the Manhang Formation of the Samcheock coal fields and the Oeumri Formation(the Middle to Late Carboniferous) of the Hwasun coal field.

• Journal of the Korean earth science society
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• v.40 no.2
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• pp.163-176
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• 2019

The Potosinian geological basement in central Mexico is comprised of the Upper Paleozoic metamorphic rocks, which crop out on the Sierra de Catorce nucleus located in the northeastern part of the state. The sedimentary sequence that covers unconformably the Paelozoic basement is represented by an Upper Triassic marine sedimentary sequence, correlating to the Zacatecas Formation and the Upper Triassic continental Huizachal Formation red beds, which in turn are covered either by La Joja Formation Jurassic red beds or by Upper Jurassic marine sediments. This sequence is overlain by the conformable Cretaceous calcareous marine sedimentary rocks in all the state of San Luis Potosi. The Cenozoic sequence unconformably covers some of the aforementioned rocks and is represented by undifferentiated volcanic rocks as well as by marine clastic rocks. The existing intrusive igneous rocks are felsic to intermediate composition, and they intrude the metamorphic basement and sedimentary rocks. Conglomerates with evaporitic sediments were deposited during the Pleistocene. The Quaternary sequence includes basalt flows, piedmont deposits, alluvium, and occasionally evaporites and caliche layers. In the state of San Luis Potosi, a great diversity of mineral deposit types is known as both metallic and nonmetallic. The host rocks of these deposits vary from one another including formations that represent from Paleozoic up to Tertiary. The mineralization age corresponds approximately to Tertiary (75%), and is mainly epigenetic. Conclusively, the data on geology and mineralization in San Luis Potosi, Mexico are helpful to predict a hidden ore body and select promising mineralized zone(s) when the domestic company makes inroads in the mining sector of Mexico.

• Journal of the Speleological Society of Korea
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• v.2 no.2
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• pp.18-21
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• 1976

각종지질도와 지질도폭에 의거하여 적화암지역이 분포한 고생대에서 중생대초에 속하는 조선계와 평안계를 우선 찾아야 할것애다. 그러나 전북 지방에 있어서는 조선계는 거의 찾아 볼수 없고 평안계는 몇몇 지역에 분포하고 있었다. 평안계는 상부 석탄기(Upper Carboniferous)에서 삼첩기(Trissic)에 형성한 지층이다. (중략)

• Proceedings of the Mineralogical Society of Korea Conference
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• 2002.10a
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• pp.1-15
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• 2002

조사지역에는 고생대 캠브리아기의 장산규암층, 묘봉층, 풍촌층, 화절층 및 오도비스기의 동점층, 두무동층, 막동층, 그리고 이들과 부정합 관계인 중생대 쥬라기의 사평리 역암이 분포한다. 위의 지층들은 북동-남서방향으로 발달하는 두 개 조의 드러스트 단층과 이에 수반된 후향 드러스트 단층 및 습곡구조에 의해 분포가 지배된다 이들 지층 중 경제 지층인 풍촌층은 암상의 특성에 따라 하부석회암대, 중부백운암대, 상부석회암대(고품위대)로 세분되며, 이 중 상부석회암대가 고품위용으로 개발대상이 된다. 상부석회암대는 백색-유백색의 치밀질 괴상석회암, 담회색 괴상 석회암, 어란상 석회암 등으로 구성되는데, 평균품위는 $SiO_2\;0.40\%,\;A1_2O_3\;0.15\%,\;Fe_2O_3\;0.15\%,\;CaO\;54.2\%,\;MgO\;1.07\%,$ 백색도 85.7로 중탄용이나 생석회 및 소석회 등 화학공업용으로 사용가능한 범위를 보여준다 고품위대의 두께는 평균 약 40m이나 드러스트 단층 등의 구조요소에 의해 $2\~3$회 반복되어 분포하기도 하고 지역에 따라 두께가 $80\~90m$까지 두꺼워지기도 한다. 상부석회암대의 석회석을 중탄용, 소성용, 탈황용 등으로 개발을 위해서는 사전에 충분한 정밀시추탐사를 시행하여 그 부존규모 및 개발가능구간 확인이 선행되어야 한다.

• Proceedings of the KSEEG Conference
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• 2002.10a
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• pp.1-15
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• 2002

조사지역에는 고생대 캠브리아기의 장산규암층, 묘봉층, 풍촌층, 화절층 및 오도비스기의 동점층, 두무동층, 막동층, 그리고 이들과 부정합 관계인 중생대 쥬라기의 사평리 역암이 분포한다. 위의 지층들은 북동-남서방향으로 발달하는 두 개 조의 드러스트 단층과 이에 수반된 후향 드러스트 단층 및 습곡구조에 의해 분포가 지배된다 이들 지층 중 경제 지층인 풍촌층은 암상의 특성에 따라 하부석회암대, 중부백운암대, 상부석회암대(고품위대)로 세분되며, 이 중 상부석회암대가 고품위용으로 개발대상이 된다. 상부석회암대는 백색-유백색의 치밀질 괴상석회암, 담회색 괴상 석회암, 어란상 석회암 등으로 구성되는데, 평균품위는 SiO$_2$ 0.40%, A1$_2$O$_3$ 0.15%, Fe$_2$O$_3$ 0.15%, CaO 54.2%, MgO 1.07%, 백색도 85.7로 중탄용이나 생석회 및 소석회 등 화학공업용으로 사용가능한 범위를 보여준다. 고품위대의 두께는 평균 약 40m이나 드러스트 단층 등의 구조요소에 의해 2～3회 반복되어 분포하기도 하고 지역에 따라 두께가 80～90m까지 두꺼워지기도 한다 상부석회암대의 석회석을 중탄용, 소성용, 탈황용 등으로 개발을 위해서는 사전에 충분한 정밀시추탐사를 시행하여 그 부존규모 및 개발가능구간 확인이 선행되어야 한다.

• Journal of the Korean earth science society
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• v.21 no.3
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• pp.250-257
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• 2000

Two species of fusulinids, viz., Pseudoschwagerina paraborealis and Quasifusulina sp. are described from the limestone core sample(90-B-1). The core sample was obtained from Imgokri, Boeungun, Chungcheongbukdo, Korea. Recognition of Pseudoschwagerina helped the authors to establish the Pseudoschwagerina Zone. Pseudoschwagerina paraborealis has been reported from the Bamchi Formation of Yeongweol coalfield in Korea and also from the Asselian and Sakmarian strata in Eurasia. The occurrence of Pseudoschwagerina paraborealis in the Boeun coalfield demonstrates the existence of the early Permian strata that are equivalent to the Bamchi Formation of Yeongweol coalfield. The authors report Quasifusulina sp. which indicates the early Permian period as well as Pseudoschwagerina paraborealis. It is the first time that the species of early Permian fusulinids are identified from the Boeun coalfield.

• Korean Journal of Mineralogy and Petrology
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• v.34 no.1
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• pp.69-81
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• 2021

The exposed rocks in the Zacatecas state include mainly Mesozoic sedimentary and volcanic, Cenozoic volcanic and plutonic rocks. Paleozoic metamorphic rocks found in the northwestern portion of the state are considered as the most ancient rocks. These rocks correspond to the Caopas Formation which underlays the Later Paleozoic Rodeo Formation. The Mesozoic sequences are represented by a marine sedimentary sequence of the Later Triassic and the red beds of the Triassic-Jurassic Nazas Formation. The marine sediments of the Upper Jurassic overlay the Nazas Formation or metamorphic rocks from the Paleozoic. The Cretaceous sequences comprises marine sedimentary rocks in the north and northeast, and a volcanosedimentary set in the center and southeast. The Cenozoic is represented by volcanic nondifferentiated rocks, intrusive igneous rocks of acid and intermediate composition, and continental conglomerates with evaporitic sediments. The Quarternary sequences includes basalts, piedmont deposits, alluviums and occasionally, layers of evaporites and saltpeter. Furthermore, a great diversity of mineral deposits of both metallic and nonmetallic types occur in Zacatecas state. The rocks composing these deposits are extremely varied and include formations from Paleozoic to Tertiary. The mineralization age of ore deposits corresponds to the Tertiary in approximately 90%, and their genesis is mainly considered as epigenetic.

• Economic and Environmental Geology
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• v.50 no.6
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• pp.525-535
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• 2017

Exhumation mechanism of migmatite in orogenic belts provides insights into thermo-mechanical evolution of lithosphere in association with orogeny. This study deals with kinematics of structures in and around the Gwangcheon Gneiss, as a preliminary study on exhumation mechanism, which is a main constituent of a domal structure (viz., Oseosan Dome) in the Hongseong area, southwestern margin of the Gyeonggi massif. Geological structures in the Gwangcheon Gneiss, which mainly comprises southern and northwestern part of the Oseosan Dome, generally have kinematic component of top-outward shear. This feature is likely to represent diapiric dome-up movement. In addition, a high strain zone, by which the tectonic domain involving the Gwangcheon Gneiss is bounded on the west, show structural features with normal sense of shear component. Taking available (thermo)chronological data into account, it is interpreted that activation of the high strain zone and exhumation of the Gwangcheon Gneiss occurred during Late Triassic, when the Gyeonggi massif was widely affected by post-collisional processes. It means that the Gwangcheon Gneiss was diapirically moved up and exhumed in the footwall of extensional high strain zone in association with Triassic post-collisional processes.